Near-Surface and Bulk Behavior of Bicontinuous Microemulsions

Jul 7, 2016 - The effect of hydrostatic pressure on the structure of a bicontinuous microemulsion in the presence of a solid interface has been studie...
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Near-Surface and Bulk Behavior of Bicontinuous Microemulsions under High-Pressure Conditions Melanie Berghaus,† Michael Paulus,‡ Paul Salmen,‡ Samy Al-Ayoubi,† Metin Tolan,‡ and Roland Winter*,† †

Physical Chemistry I − Biophysical Chemistry, TU Dortmund, D-44227 Dortmund, Germany Fakultät Physik/DELTA, TU Dortmund, D-44221 Dortmund, Germany



ABSTRACT: The effect of hydrostatic pressure on the structure of a bicontinuous microemulsion in the presence of a solid interface has been studied by X-ray reflectometry and compared to the bulk behavior determined by small-angle X-ray scattering. Surfaceinduced lamellar ordering is observed close to the hydrophilic interface, which persists upon compression. The lamellar domains are compressed, but the correlation length of lamellar order does not change with pressure. SAXS measurements on the bulk microemulsion revealed an increased order upon pressurization. Although pressure can cause the formation of highly ordered lamellar phases from ordered bicontinuous cubic phases, such a scenario is not observed for the disordered analogue studied here. High pressure increases the stiffness of the interfacial surfactant layer, but this is not sufficient to overcome the loss in conformational entropy that would result from a transition to an ordered lamellar phase. Possible technological and biological implications of our results are briefly discussed.



INTRODUCTION Much attention has been paid in recent years to lyotropic mesophases, such as lamellar, hexagonal, and bicontinuous cubic structures of lipid systems, or microemulsions that are composed of surfactants, oil, and water.1,2 They play an important role in many technological processes and also serve as model systems of biological membrane architectures and the phase transitions taking place in these systems.2−5 For example, lamellar-to-nonlamellar phase transitions in lipid model systems have been investigated as they are significant in a variety of dynamic membrane-associated biological processes.5−7 For example, the transition from a fluid lamellar phase to an inverse bicontinuous cubic phase has been studied to reveal mechanistic information about the final step in vesicle fusion. During this process, transient contacts between lipid bilayer membranes are formed, which widen and break to form interlamellar attachments or fusion pores.5 Generally, the stability of lyotropic lipid mesophases is dependent on the ionic strength, pH, temperature, and pressure, and so any of these variables can be used as a trigger to study phase transitions between different mesophase structures.8−11 Pressure changes have a significant advantage over other triggers, as the pressure is readily transmitted, pressure-induced changes are generally fully reversible, and pressure does not change the thermal energy of the system and the intramolecular bonding up to GPa pressures.8 High hydrostatic pressure (HHP) application has the additional advantage that the surfactant’s conformational order and hence packing parameter can be varied continuously by pressure modulation. Apart from its physicochemical use as a thermodynamic parameter, high hydrostatic pressure studies have an important biological component: enhancing the understanding of life under © 2016 American Chemical Society

extreme conditions. In fact, the greatest portion of our biosphere on Earth is in the realm of environmental extremes, including the cold and high-pressure habitats of marine depths. Species are even found on the deepest ocean floor (at 11 000 m depth) and in the deep biosphere, where pressures up to the 100 MPa (1 kbar) level are reached.8,12 Regarding pressure effects on lyotropic mesophases, essentially ordered lipid structures have been studied in recent years.5,9−11 What is much less explored, though also of high biological and technical relevance, is the effect of conformational disorder as well as the presence of interfaces (hard and soft matter) on such mesophase transitions. Relevant applications range from studies of nonlamellar lipid architectures in cellulo at high pressures to strategies aiming at enhancing oil recovery using microemulsions in boreholes. To mimic the effect of disorder and the presence of interfaces, we studied the pressure-response on the structure of a disordered bicontinuous microemulsion (BME) at a solid interface by X-ray reflectivity (XRR) measurements and, for comparison, the behavior of the bulk solution by small-angle X-ray scattering (SAXS). BMEs are ternary systems that consist of an interwoven network of water and oil channels, separated by a monomolecular surfactant film. A microemulsion is called bicontinuous if the oil and the water networks span the whole system. BMEs can, for example, serve as a model system for cellular compartmentalization. They also serve as reaction media for biocatalysis, polymer synthesis, the dispersion of drugs, the extraction of contaminated material, and oil recovery.13−16 Received: June 5, 2016 Revised: July 6, 2016 Published: July 7, 2016 7148

DOI: 10.1021/acs.jpcb.6b05639 J. Phys. Chem. B 2016, 120, 7148−7153

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The Journal of Physical Chemistry B

Radiation Facility (ESRF) in Grenoble, France. The energy used was 16 keV, and the sample to detector distance was 2 m. The samples were exposed to the beam for 0.2 s for each measurement. All measurements were performed at a constant temperature of 20 °C. Data were background corrected using the SAXSutilities Package provided by ESRF.27 The experimental data was fit according to the Teubner−Strey model28 using the software SASfit.29

Owing to their low interfacial tension, curvature effects play an important role in BMEs. They are everywhere curved into saddle-like shapes to multiply interconnect throughout the sample in the three dimensions of space. The persistence length of the interfacial film, ξp, describes the length over which the film is locally flat; it is given by ξp = l exp(2πκ/kBT) where l is the molecular length of the surfactant.1,17 High ξp values indicate flat surfaces, whereas low values are found with highly curved interfaces, which is the case if the bending elastic constant, κ, of the film is as low as of the order of kBT. Interestingly, some BMEs show a transition from their bicontinuous structure in the bulk to a lamellar phase when approaching a surface, as revealed by neutron reflectometry and theory, recently.18,19 Further, grazing incidence neutron spin echo spectroscopy (GINSES) revealed that the dynamics within such a system is significantly faster in the proximity of a hydrophilic solid interface.20,21 The effect of pressure on such near-surface layering still needs to be explored. In our study, we used a mixture consisting of equal volumes of water and n-octane (oil), and 16 wt % of the surfactant tetraethyleneglycol decanoyl ether (C10E4) to create a BME featuring such phase behavior.



RESULTS AND DISCUSSION The near-surface behavior of the microemulsion was investigated using XRR measurements. As shown in Figure 1, all



EXPERIMENTAL METHODS Sample Preparation. The distilled water used was of Milli-Q purity. N-Octane was purchased from Fluka (Taufkirchen Germany), the surfactant tetraethyleneglycol decanoyl ether, C10E4, was purchased from Bachem (Bubendorf, Switzerland). Equal volumes of water and n-octane were combined, and a sufficient amount of C10E4 was added to obtain a final concentration of 16 wt % surfactant. All compounds were mixed by vigorous agitation. The undoped and polished silicon wafers used for the reflectivity measurements with a roughness of 3 Å were provided by Wacker Siltronic (Burghausen, Germany). They were cut into pieces of 8 × 8 mm, rinsed and hydrophilized in a solution of NH4OH and H2O2 (RCA cleaning22), and stored in deionized water until usage. X-ray Reflectivity (XRR) Measurements. In the X-ray reflectivity experiment, the specular reflected intensity is measured as a function of the wave vector transfer qz = (4π/λ) sin(θ) perpendicular to the sample’s surface. Thus, only information on the laterally averaged electron density profile is obtained from the XRR data. Depending on the maximum accessible wave vector transfer qz, the spatial resolution in the z-direction can reach sub-angstroms. The X-ray reflectivities were recorded at beamline BL9 of the Synchrotron radiation source DELTA, Dortmund, Germany, using the 27 keV reflectivity setup.23 All measurements were performed at a constant temperature of 20 °C. A high hydrostatic pressure cell was used, which allows the application of pressures up to 500 MPa.24 After preparation of the sample, the liquid was filled into the cell and the pressure was raised to 5 MPa, to supplant air in the cell. Subsequently, reflectivities were measured at different pressures using a PILATUS 100k detector for photon detection. To characterize the solid substrate, the reflectivity curve with pure water above the silicon wafer was measured. The detected signal was normalized to the incoming photon flux and analyzed using the Parratt algorithm25 in combination with the effective density model.26 Small-Angle X-ray Scattering (SAXS) Measurements. Pressure-dependent SAXS measurements were performed in a home-built high hydrostatic pressure cell with diamond windows24 at Beamline ID02 at the European Synchrotron

Figure 1. (a) Correlation peaks extracted from X-ray reflectivity measurements of the microemulsion near the surface of a hydrophilic Si-wafer at different pressure conditions. The position of the correlation peak associated with the lamellar phase, q0, shifts toward higher qz-values upon pressurization. (b) Decrease of the corresponding size of the alternating arrangements of water and oil, dsurface = 2π/q0, with pressure. Error bars were derived from Gaussian fits to determine the position of the peak maximum, q0.

reflectivity curves show a correlation peak, which shifts to higher qz-values upon pressurization. This correlation peak can be attributed to a (disordered) lamellar phase whose domain size of alternating lamellar arrangements,18,19 dsurface = 2π/q0, can be derived from the position of the correlation peak, q0, which is compressed from about 150 Å at near-ambient pressure (5 MPa) to 120 Å at 400 MPa. The corresponding compressibility of the lamellar lattice, ddsurface/dp, amounts to 0.1 Å MPa−1. Corresponding real-space electron density profiles (EDP) were calculated using the Parratt algorithm25 to fit the reflectivity curves at selected pressures (50, 200, and 400 MPa), as can be seen in Figure 2. To determine the electron density profiles, we fitted the entire qz-range from 0.02 to 0.6 Å−1. Such a wide q-range is needed to obtain the EDP with sufficient accuracy. The location of the Si wafer with the highest electron density is defined as z = 0. A thin layer with the electron density of water 7149

DOI: 10.1021/acs.jpcb.6b05639 J. Phys. Chem. B 2016, 120, 7148−7153

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an increase of the electron density, which approaches the bulk value of the microemulsion beyond about 450 Å. With increasing pressure, the maxima of the oscillations in the EDP shift toward the surface, indicating marked compression of the lamellar layers, which is probably due to the about 3-fold larger compressibility of n-octane compared to water (isothermal compressibility κT(water) = 0.459 GPa−1, κT(n-octane) = 1.282 GPa−1 at room temperature and ambient pressure31−33). The density increase of the system upon compression is also reflected in the overall increase of the EDPs. Interestingly, we did not find an increase in the number of near-surface layers at high pressures. Within the bulk phase, the pressure-dependent structure of the bicontinuous microemulsion was determined by smallangle X-ray scattering (Figure 3). All scattering intensity profiles

Figure 2. (a) Fits according to the Parratt algorithm25 to the experimental X-ray reflectivity data of water at 5 MPa and of the microemulsion near the surface of a Si-wafer at 5, 200, and 400 MPa to determine electron density profiles. Curves were shifted for clarity. (b) Corresponding real-space electron density profiles. The oscillations in the electron density reflect the alternating water/oil domains, which are compressed by applying pressure. (c) Illustration of the water (white) and oil (black) domains based on the electron density profile of the emulsion at 5 MPa.

(∼8 Å, 2−3 layers of H2O) is visible in direct proximity to the hydrophilic Si surface. A similar layer was also found at the liquid−air interface.19 In contrast, in direct proximity to a hydrophobic interface, an oil layer was observed.30 Thicker layers of alternating water and oil domains close to the surface of the Si wafer are visible as oscillations in the electron density (corresponding to about three layers), which approach the electron density of the bulk solution at a distance of about 450 Å away from the surface for the EDP at 5 MPa. This distance, which can be regarded as the correlation length of the lamellar interface, ξsurface, decreases slightly with pressure, which is in good agreement with the compression of the layers discussed above. Neutron reflectivity studies found that ξsurface of the lamellar phase is about 300 Å at atmospheric pressure,18 which is in a similar range as the correlation length of the hydrophilic surfaceinduced lamellar interface found in our experiments. The overall electron density close to the surface is significantly lower than in the bulk solution about 500 Å away from the surface. This is probably due to a laterally extended surfactant/oil layer close to the interface and is a consequence of the ordering effect the hydrophilic interface imposes on the arrangement of the surfactant molecules, which are supposed to bind to the wet hydrophilic solid interface by their hydrophilic headgroups. With increasing distance, z, from the surface, lamellar ordering is reduced, finally vanishing after about 2−3 water−oil layers. The increased disorder is most likely due to the fact that the lamellae get increasingly perforated, leading to

Figure 3. (a) Bulk scattering intensity profiles, I(q), of the bicontinuous microemulsion at different pressures in double-logarithmic representation. Red solid lines indicate fits according to the Teubner−Strey model.28 Second-order peaks arising under pressurization are indicated by an asterisk. Curves were shifted for clarity. (b) Pressure-dependent changes in the domain size, dm,bulk, and correlation length, ξm,bulk, of the bicontinuous microemulsion derived from fits using the Teubner−Strey model. The decrease of dm,bulk reveals a high compressibility of the domains, whereas the correlation length ξm,bulk, i.e., the coherent length of the local periodic domain structure, does not change markedly. Error bars are standard deviations from the evaluation of three independent measurements.

show a broad correlation peak at scattering vector q0, which shifts to higher scattering angles upon pressurization, indicating a decrease of the domain size of the bicontinuous phase. No phase transition to a different mesophase structure is observed up to 400 MPa. The data were further analyzed by fitting the results to the Teubner−Strey model.28 The overall quality of the fits decreases with increasing pressure. However, in the region of the correlation peak, the fits are of sufficiently accuracy that the parameters for the average domain spacing in the bulk, dm,bulk ≈ 2π/q0, and the correlation length, ξm,bulk, which characterizes the decay of local order, can be derived. The suffix “m” characterizes 7150

DOI: 10.1021/acs.jpcb.6b05639 J. Phys. Chem. B 2016, 120, 7148−7153

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The Journal of Physical Chemistry B the bicontinuous microemulsion structure. As expected, at large q, the Porod law I(q) ∝ q−4 indicates a sharp water−oil interface. The domain size decreases from about 240 to 140 Å upon pressurization, which is in good agreement with the domain size derived directly from the position of the correlation peak (2π/q0) and the pair distance distribution function, P(r), calculated by indirect Fourier transformation (Figure 4). Most of

Figure 5. Decrease in the disorder parameter Dm of the bulk phase of the microemulsion with pressure. Error bars are standard deviations from three independent measurements.

however. These findings are in agreement with the observation that the surfactant monolayers become more rigid with increasing pressure as revealed by neutron spin echo (NSE) experiments for a similar system.36 This can be attributed to a decreased flexibility in the hydrophobic part of the surfactant molecules. At much higher pressures, the increase in bending modulus of the interface and a marked decrease of the packing parameter (the ratio of the volume of the surfactant molecule and the product of the area of the polar headgroup and the tail length) might still lead to a phase change to a lamellar phase, however. The soft elastic sheets of the BME exhibit thermal undulations whose amplitude increases with temperature. Conversely, such undulation forces should decrease with the increasing bending modulus and the reducing packing parameter of the surfactant. Hence, an increase of pressure could be expected to induce the transition from a bicontinuous to a lamellar structure, and thus also of near-surface lamellar ordering. However, a freezing-in of the thermally excited long-wavelength modes due to an increased bending modulus upon compression of the system would reduce the entropy associated with these thermal excitations and lead to an increase in free energy. Therefore, the entropy term seems to outweigh the increase in bending energy also at high pressures, thereby preventing the system from undergoing a phase transition to a more ordered lamellar phase, at least in the pressure range covered in these experiments.

Figure 4. Pressure-dependent changes in the real-space pair distance distribution functions, P(r), of the bulk phase of the microemulsion derived from the SAXS data by indirect Fourier transformation. (a) Experimental data (open symbols) with according fits (solid lines). (b) P(r) functions obtained by indirect Fourier transformation.

the compression takes place in the pressure regime between 50 and 200 MPa, in which the dm,bulk value decreases from 240 to 160 Å, its compressibility, ddm,bulk/dp, amounting to 0.4 Å MPa−1. At higher pressures, the domain size of the bicontinuous phase gets only slightly more compressed, about 10 Å between 200 and 400 MPa, corresponding to a ddm,bulk/dp value of 0.1 Å MPa−1. The overall decrease of the compressibility of the domain structure upon compression is reminiscent of that of single component bulk liquids.34 In comparison to the domain size, the change in the correlation length, ξm,bulk, with pressure is relatively small. The value for ξm,bulk is about 110 Å throughout the whole pressure range covered. At 5 MPa, this value is about dm,bulk/2, indicating correlations only between nearest neighbor domains. The compression of the domain size in combination with the essentially constant correlation length leads to a marked change in the ratio between dm,bulk and ξm,bulk with increasing pressure. The parameter Dm = dm,bulk/(2πξm,bulk), which is a measure of the disorder in the system (disorder parameter),34,35 experiences a significant decrease up to 200 MPa (Figure 5), from 0.33 to 0.22; i.e., the structural order of the system increases with pressurization. The appearance of a slight second-order correlation peak at 2q0 in the scattering curves supports this observation. The overall bicontinuous structure remains preserved,



CONCLUSIONS To summarize, our results show that bicontinuous microemulsions form a thin lamellar phase close to hydrophilic interfaces, and this layer persists upon compression. Due to the wide qz-range covered in the XRR measurements, we could analyze the electron density profile in the proximity to the hydrophilic solid−liquid interface in detail. About 2−3 lamellar layers could be resolved, displaying increasing disorder with increasing distance from the solid interface. We found that the lamellar domains are compressed with increasing pressure and that the correlation length of lamellar order decreases slightly with pressure. The SAXS measurements on the bulk microemulsion phase revealed an increased order of the bicontinuous phase upon pressurization. However, no phase transition is observed up to 400 MPa. Though pressure has been shown to cause the formation of highly ordered lamellar phases from ordered bicontinuous cubic lipid phases, such a scenario is not observed for the disordered BME system studied here. 7151

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High pressure leads to an increase of the stiffness and hence the bending modulus of the interfacial layer, but this is not sufficient to overcome the loss in conformational entropy that would result from a phase transition to a more ordered lamellar phase. Our observations might have several implications, ranging from pressure effects on emulsions in deep subsurface oil recovery, up to biologically relevant problems dealing with lamellar-to-nonlamellar phase transitions in organisms thriving in the deep sea, where pressures up to the 100 MPa pressure level and beyond are encountered.



AUTHOR INFORMATION

Corresponding Author

*R. Winter. E-mail: [email protected]. Phone: +49 231 755 3900. Fax: +49 231 755 3901. Notes

The authors declare no competing financial interest.



ACKNOWLEDGMENTS We gratefully acknowledge financial support from the DFG Forschergruppe FOR 1583 and in part by the Cluster of Excellence RESOLV (EXC 1069). P. Salmen acknowledges the DFG Forschergruppe FOR 1979 for funding. The authors thank the DELTA team and the ESRF for providing Synchrotron radiation. We are especially grateful to Dr. Johannes Möller at the ESRF for providing assistance in using beamline ID02.



ABBREVIATIONS HHP, high hydrostatic pressure; BME, bicontinuous microemulsion; XRR, X-ray reflectivity; SAXS, small-angle X-ray scattering; EDP, electron density profiles



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